On some nearly viscometric flows of viscoelastic liquids |
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Authors: | Professor A Siginer |
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Institution: | (1) Department of Mechanical Engineering, Auburn University, 201 Ross Hall, 36849 Auburn, AL, USA |
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Abstract: | Superposition of oscillatory shear imposed from the boundary and through pressure gradient oscillations and simple shear is investigated. The integral fluid with fading memory shows flow enhancement effects due to the nonlinear structure. Closed-form expressions for the change in the mass transport rate are given at the lowest significant order in the perturbation algorithm. The elasticity of the liquid plays as important a role in determining the enhancement as does the shear dependent viscosity. Coupling of shear thinning and elasticity may produce sharp increases in the flow rate. The interaction of oscillatory shear components may generate a steady flow, either longitudinal or orthogonal, resulting in increases in flow rates akin to resonance, and due to frequency cancellation, even in the absence of a mean gradient. An algorithm to determine the constitutive functions of the integral fluid of order three is outlined.Nomenclature
A
n
Rivlin-Ericksen tensor of order .
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A
k
Non-oscillatory component of the first order linear viscoelastic oscillatory velocity field induced by the kth wave in the pressure gradient
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d
Half the gap between the plates
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e
x, e
z
Unit vectors in the longitudinal and orthogonal directions, respectively
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G(s)
Relaxation modulus
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G
History of the deformation
-
Stress response functional
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I()
Enhancement defined as the ratio of the frequency dependent part of the discharge to the frequencyindependent part of it at the third order
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I
*()
Enhancement defined as the ratio of the increase in discharge due to oscillations to the total discharge without the oscillations
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k
Power index in the relaxation modulus G(s)
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k
i
–1
Relaxation times in the Maxwell representation of the quadratic shear relaxation modulus (s
1, s
2)
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m
i
–1, n
i
–1
Relaxation times in the Maxwell representations of the constitutive functions 1(s
1,s
2,s
3) and 4 (s
1, s
2,s
3), respectively
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P
Constant longitudinal pressure gradient
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p
Pressure field
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mx
,(3)
nz
,(3)
Mean volume transport rates at the third order in the longitudinal and orthogonal directions, respectively
- 0,(3), 1,(3)
Frequency independent and dependent volume transport rates, respectively, at the third order
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s = t-
Difference between present and past times t and |
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Keywords: | Oscillating and pulsating flows flow enhancement integral fluid of order three nearly viscomeiric flow |
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